1. 个人研究方向
1. . Constructing metallosalen poly(ionic liquid)s to boost photocatalytic CO2 reduction. Journal of Materials Chemistry A, 2024.
2. 姜淑超. An Effective Strategy to Boost Formic Acid Dehydrogenation over Pd/AC-NH2 Catalyst through Pd Size Control. ACS Applied Materials & Interfaces, 16, 55306-55313, 2024.
3. 吕科燃. Bifunctional role of mechanical catalysis approach accelerates CO2 hydrogenation under low temperature. Chemical Engineering Journal, 503, 2024.
4. 陈晓芳. Simulating Crystal Structure, Acidity, Proton Distribution, and IR Spectra of Acid Zeolite HSAPO-34: A High Accuracy Study. Molecules, 28, 2023.
5. . Pt/Ni single-atom alloy boosts mechano-pyrolysis of alkane into hydrogen. Applied Catalysis B: Environmental, 353, 2024.
6. Fan, Dequan. Hybrid exchange methods regulate Cu+ location on Cu-Y zeolites and improve CO adsorption capacity and selectivity. Separation and Purification Technology, 344, 2024.
7. . Machine learning aided design of single-atom alloy catalysts for methane cracking. NATURE COMMUNICATIONS, 15, 2024.
8. 丛蝶. Hydrogen-Bond-Network Breakdown Boosts Selective CO2 Photoreduction by Suppressing H2 Evolution. ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 2024.
9. 杨君侠. Hydrogenation of NOx into ammonia under ambient conditions: From mechanistic investigation to multiphase catalysis. Applied Catalysis B: Environmental, 329, 2023.
10. 姜淑超. Ambient Hydrogen Storage and Release Using CO2and an l -Arginine-Functionalized PdAu Catalyst via pH Control. ACS Catal. , 12, 14113-14122, 2022.
11. 张玲. Manipulate the acidity of gallium doped Silicalite-1 to optimize methanol to propene performance. Chemical Engineering Journal, 458, 2023.
12. 涂芮. Single-atom alloy Ir/Ni catalyst boosts CO2 methanation via mechanochemistry. NANOSCALE HORIZONS, 2023.
13. Yang, Junxia. Hydrogenation Reactions with Synergistic Catalysis of Pd single atoms and nanoparticles under Near-Ambient Conditions.. Chemistry a European Journal, 29, 2022.
14. 姜淑超. Efficient dehydrogenation of high-concentration formic acid over PdAu/AC-NH<sub>2</sub> catalysts without additives under ambient conditions. NEW JOURNAL OF CHEMISTRY, 47, 1081, 2023.
15. . Additive-free CO2 hydrogenation to pure formic acid solution via amine-modified Pd catalyst at room temperature. GREEN CHEMISTRY, 25, 6025-6031, 2023.
16. . Mechanical vibration reactor achieves CO2 methanation assisted by ruthenium modified nickel milling balls. Chemical Engineering Journal, 471, 2023.
17. 杨君侠. Mechano-catalysis boosts glycolaldehyde conversion to tetroses over a new Zn-COF catalyst. NEW JOURNAL OF CHEMISTRY, 47, 558-562, 2022.
18. 姜淑超. Ambient Hydrogen Storage and Release Using CO2 and an L-Arginine-Functionalized PdAu Catalyst via pH Control. Acs catalysis, 12, 14113, 2022.
19. 方旭. Poly(ionic liquid)s for Photo-Driven CO2 Cycloaddition: Electron Donor-Acceptor Segments Matter. ADVANCED SCIENCE, 10, 2023.
20. 姜淑超. Ambient CO2 capture and conversion into liquid fuel and fertilizer catalyzed by a PdAu nano-alloy. CELL REPORTS PHYSICAL SCIENCE, 4, 2023.
21. . Poly(ionic liquid)s for Photo-Driven CO2 Cycloaddition: Electron Donor-Acceptor Segments Matter. ADVANCED SCIENCE, 10, 2023.
22. . Heteronuclear Dual Single-Atom Catalysts for Ambient Conversion of CO2 from Air to Formate. Acs catalysis, 13, 3915, 2023.
23. Zhang, Ling. Synergetic effect between Pd2+ and Ir4+ species promoting direct ethane dehydrogenation into ethylene over bimetallic PdIr/AC catalysts. CATALYSIS SCIENCE & TECHNOLOGY, 12, 3874-3885, 2022.
24. 翟盛良. Liquid Sunshine: Formic Acid. Journal of Physical Chemistry Letters, 2022.
25. 任国庆. Ambient hydrogenation of carbon dioxide into liquid fuel by a heterogeneous synergetic dual single-atom catalyst. CELL REPORTS PHYSICAL SCIENCE, 3, 2022.
26. 翟盛良. Rational Design of Synergistic Structure Between Single-Atoms and Nanoparticles for CO2 Hydrogenation to Formate Under Ambient Conditions. Frontiers in Chemistry, 10, 2022.
27. 任国庆. Ambient hydrogenation of carbon dioxide into liquid fuel by a heterogeneous synergetic dual single-atom catalyst. CELL REPORTS PHYSICAL SCIENCE, 3, 2022.
28. 翟盛良. Rational Design of Synergistic Structure Between Single-Atoms and Nanoparticles for CO2 Hydrogenation to Formate Under Ambient Conditions. 10, 957412, 2022.
29. 王洪磊. In silico design of dual-doped nitrogenated graphene (C2N) employed in electrocatalytic reduction of carbon monoxide to ethylene. Journal of Materials Chemistry A, 10, 4703, 2022.
30. Fan, Dequan. Cuprous species distribution over CuCl/NaY dependent on acidity and their CO Adsorption/desorption performance study. Chemical Engineering Journal , 433, 2022.
31. 邓启文. Hydrogen and CO2 storage in high surface area covalent triazine-based frameworks. MATERIALS TODAY ENERGY, 18, 2020.
32. 任国庆. Ambient hydrogenation of carbon dioxide into liquid fuel by a heterogeneous synergetic dual single-atom catalyst. CELL REPORTS PHYSICAL SCIENCE, 3, 2022.
33. 方旭. Bifunctional poly(ionic liquid) catalyst with dual-active-center for CO2 conversion: Synergistic effect of triazine and imidazolium motifs. JOURNAL OF CO2 UTILIZATION, 54, 2021.
34. 赵文玲. Unblocked intramolecular charge transfer for enhanced CO2 photoreduction enabled by an imidazolium-based ionic conjugated microporous polymer. 应用催化B, 300, 2021.
35. 冯念云. Conjugated microporous polymer foams with excellent thermal insulation performance in a humid environment. RSC ADVANCES, 11, 13957, 2021.
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1. 高等无机化学
2. 高等无机化学
3. 高等无机化学
4. 高等无机化学
5. 高等无机化学
